Spin-phonon-charge coupling in the two-dimensional honeycomb lattice compound Ni2Te3O8

A two-dimensional honeycomb-structured magnet Ni2Te3O8 was synthesized, characterized, and comprehen-sively investigated for its intriguing physical properties. DC magnetization, specific heat, and neutron diffraction revealed a long-range commensurate antiferromagnetic ordering at TN & SIM; 35 K with a propagation vector k = (100). The magnetic sublattice comprises stacking distorted honeycomb layers along the a axis. The Ni2+ spins on the honeycomb lattice are essentially pointing out of the layers and are antiferromagnetically coupled to the neighboring spins. Temperature (T) and magnetic field (H) dependent dielectric measurements indicated an apparent anomaly near TN, accompanied by a weak magnetodielectric effect. Raman mode renormalization and lattice anomalies near TN demonstrated spin-lattice coupling through magnetoelastic and spin-phonon interactions. These findings highlight the fascinating interplay between spin, charge, and phonon degrees of freedom in Ni2Te3O8.

Automated summary

A two-dimensional honeycomb-structured magnet Ni2Te3O8 with intriguing physical properties was synthesized, characterized, and comprehensively investigated. The study revealed a long-range commensurate antiferromagnetic ordering at TN ≈ 35 K and observed spin-lattice coupling and magnetodielectric effect.